KR20180058805A - Method and apparatus for scheduling and uplink transmission of uplink transmission resources - Google Patents

Abstract

The present invention discloses a scheduling and uplink transmission method and apparatus for uplink transmission resources to realize a preliminary allocation of uplink transmission resources on an unauthorized carrier so that the UE transmits an uplink signal on the pre- To prevent the scheduled UE from failing to access the channel and to implement time division multiplexing of uplink transmission resources on the unlicensed carrier. A method for scheduling an uplink transmission resource according to the present invention is characterized in that a base station establishes a pre-allocated resource in an uplink sub-frame, and the pre-allocated resource is a transmission resource on an unauthorized carrier; And the base station includes transmitting a notification of a pre-allocated resource in the uplink sub-frame to the UE.

Description

Method and apparatus for scheduling and uplink transmission of uplink transmission resources

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication technology field, and more particularly, to a method and apparatus for scheduling uplink transmission resources and an uplink transmission method.

Since the amount of mobile data traffic is constantly increasing, while the spectrum resources are becoming smaller and smaller, the construction of a network using only authorized spectrum resources or the transmission of traffic can not satisfy the demand for the amount of traffic, so the LTE (Long Term Evolution) It begins to consider transmission using the unauthorized spectrum resource. These LTE systems can be called U-LTE or Unlicensed LTE (Unlicensed LTE) systems and enhance the UE experience to ensure coverage coverage. However, it is still not clear how the current LTE system should operate on unlicensed spectrum resources.

Unauthorized spectrum If you have not planned a system to be specifically targeted, and you have not shared the unauthorized spectrum shared by wireless communication systems such as Bluetooth, WIFI (WiFi) Resources. Thus, the way in which wireless communication systems, such as LTE-U and LTE-U and WiFi, shared by different operators share unauthorized spectrum resources is a research focus and difficulty. 3GPP requires fair coexistence between wireless communication systems, and unlicensed frequency bands are implemented with the help of a primary carrier in a licensed frequency band as a secondary carrier. Listen Before Talk (LBT) is the primary means of LTE-U contention access. When performing time division multiplexing in unlicensed frequency bands, the scheduled UE behind the User Equipment (UE) that is transmitting the signal will cause it to access the channel.

As a result, the prior art does not suggest the scheduling and use of unlicensed spectrum resources.

An embodiment according to the present invention provides a scheduling and uplink transmission method and apparatus for uplink transmission resources to realize preliminary allocation of uplink transmission resources on unauthorized carriers, Link signal to prevent the scheduled UE from accessing the channel and to implement time division multiplexing of uplink transmission resources on the unlicensed carrier.

A method for scheduling an uplink transmission resource according to an embodiment of the present invention is characterized in that a base station determines a pre-allocated resource in an uplink sub-frame, the pre-allocated resource is a transmission resource on a carrier without permission; And the base station includes transmitting a notification of a pre-allocated resource in the uplink sub-frame to the UE.

According to the method, the base station determines a pre-allocated resource in an uplink sub-frame, the pre-allocated resource is a transmission resource on an unauthorized carrier, and the base station transmits a pre- Allocating uplink transmission resources on an unauthorized carrier by sending a notification of resources that have not been allocated, thereby preventing the UE from failing to transmit an uplink signal on the pre-allocated resource, thereby preventing the scheduled UE from accessing the channel , Allowing time division multiplexing of uplink transmission resources on the unlicensed carrier.

Optionally, the base station transmits a notification of a pre-allocated resource in the uplink sub-frame to the UE in a semi-statically or dynamically manner.

Optionally, when the base station transmits a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner, the base station notifies the UE via non-physical layer signaling, Transmits a notification of the allocated resource,

When the base station transmits a notice of a pre-allocated resource in the uplink sub-frame to the UE in a dynamic manner, the base station notifies the UE via physical layer signaling of the pre-allocated resource in the uplink sub-frame .

Optionally, the pre-allocated resource is used by the UE to perform an LBT.

Optionally, the notification includes indication information indicating that the UE should reserve resources in an uplink sub-frame; An uplink sub-frame in which the pre-allocated resource is located, and a position in an uplink sub-frame; And a pre-allocated resource size in an uplink sub-frame containing a pre-allocated resource, or any combination thereof.

Optionally, the pre-allocated resource is located at the head or tail of at least one of the uplink subframes.

In an uplink transmission method according to an embodiment of the present invention, a UE determines a pre-allocated resource in an uplink sub-frame, the pre-allocated resource is a transmission resource on a carrier without permission; And determining that the UE does not transmit an uplink signal in the pre-allocated resource.

Optionally, the method further comprises: performing the LBT on the pre-allocated resource if the UE fails to access the channel; Alternatively, the UE transmits an uplink signal on the uplink resource scheduled by the base station when the channel is accessed.

Optionally, the pre-allocated resources in the uplink sub-frame are preset; Alternatively, the UE may receive a notification informing a pre-allocated resource in the uplink sub-frame that the base station has transmitted in a quasi-static manner or a dynamic manner, and transmit the pre-allocated resource in the uplink sub- .

An apparatus for scheduling an uplink transmission resource according to an embodiment of the present invention includes: a preliminary allocation unit that determines a preliminarily allocated resource in an uplink subframe, and the preliminarily allocated resource is a transmission resource on a carrier with no permission; And a notification unit for transmitting a notification of the pre-allocated resource in the uplink sub-frame to the UE.

Optionally, the notifying unit transmits a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner or in a dynamic manner.

Optionally, when the notifying unit transmits a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner, the notifying unit notifies the UE via non-physical layer signaling in the uplink sub- Allocated resource in the uplink sub-frame to the UE via the physical layer signaling when the notifying unit transmits the notification of the pre-allocated resource in the uplink sub-frame to the UE in a dynamic manner And transmits a notification of the pre-allocated resource in the uplink sub-frame.

Optionally, the pre-allocated resource is used by the UE to perform an LBT.

Optionally, the notification includes indication information indicating that the UE should reserve resources in an uplink sub-frame; An uplink sub-frame in which the pre-allocated resource is located, and a position in an uplink sub-frame; And a pre-allocated resource size in an uplink sub-frame containing a pre-allocated resource, or any combination thereof.

Optionally, the pre-allocated resource is located at the head or tail of at least one of the uplink subframes.

An uplink transmission apparatus according to an embodiment of the present invention confirms a pre-allocated resource in an uplink sub-frame, and the pre-allocated resource is a transmission resource on a carrier without permission; And a second unit for determining that the uplink signal is not transmitted in the pre-allocated resource.

Optionally, the second unit performs LBT on the pre-allocated resource if the UE of the device fails to access the channel; Or transmits an uplink signal on the uplink resource scheduled by the base station when the UE belonging to the apparatus accesses the channel.

Optionally, the pre-allocated resources in the uplink sub-frame by the first unit are preset; Alternatively, the first unit may be configured to receive a notification of a pre-allocated resource in the uplink sub-frame transmitted by a base station in a semi-statically or dynamic manner, And determines the pre-allocated resources in the frame.

FIG. 1 is a diagram illustrating a method of preempting a resource in an unauthorized spectrum in a WIFI system according to an embodiment of the present invention.
2 is a diagram illustrating a mechanism for accessing a channel according to an embodiment of the present invention.
3 is a diagram illustrating a mechanism for accessing another channel of an embodiment according to the present invention.
4 is a configuration diagram of a first type frame according to an embodiment of the present invention.
5 is a configuration diagram of a second type frame according to an embodiment of the present invention.
6 is a flowchart of a scheduling method of uplink transmission resources according to an embodiment of the present invention.
7 is a flowchart of an uplink transmission method according to an embodiment of the present invention.
FIG. 8 is a diagram showing a pre-allocated resource determined by a static setting method according to an embodiment of the present invention.
9 is a diagram illustrating pre-allocated resources determined by a quasi-static setting scheme of an embodiment of the present invention.
10 is a diagram illustrating a pre-allocated resource determined by a dynamic configuration scheme according to an embodiment of the present invention.
11 is a configuration diagram of an apparatus for scheduling uplink transmission resources according to an embodiment of the present invention.
12 is a configuration diagram of an uplink transmission apparatus according to an embodiment of the present invention.
13 is a configuration diagram of another scheduling apparatus for uplink transmission resources according to the embodiment of the present invention.
14 is a configuration diagram of another uplink transmission apparatus in the embodiment according to the present invention.

An embodiment according to the present invention provides a scheduling and uplink transmission method and apparatus for uplink transmission resources to realize preliminary allocation of uplink transmission resources on unauthorized carriers, Link signal to prevent the scheduled UE from accessing the channel and to implement time division multiplexing of uplink transmission resources on the unlicensed carrier.

The LBT of the embodiment according to the present invention is the basic means of LTE-U contention access. The resource prefetching scheme in a spectrum in which the WIFI system is not permitted is a carrier CSMA / CA (Carrier Sense Multiple Access / Collision Avoidance) mechanism used in the 802.11 system as the essence of LBT technology. Listen. When the channel idle time reaches the Distributed Inter-Frame Space (DIFS), it is determined that the current channel is an idle channel. Each station that is waiting for access to the channel then enters a random backoff stage to prevent multiple stations from colliding on the same resource. In addition, to ensure fairness, each station is required not to occupy unauthorized spectrum resources for a long time, and when the occupation time reaches a certain time or the upper limit of data transmission, the spectrum resource without occupied permission is distributed to another WIFI Let the LTE system preempt the resource.

To establish a flexible and fair self-adaptive channel access mechanism, Europe requires the adoption of LBT technology at unlicensed 5150-5350MHz and 5470-5725MHz frequencies. The CCA (Clear Channel Assessment) determines whether the channel is occupied by judging whether a signal is transmitted from the current channel through energy detection.

ETSI in Europe specifies two methods of LBT in a frequency band without permission of 5 GHz. As shown in FIG. 2 and FIG. 3, frame based equipment and load based equipment (FBE) Based devices) are defined.

See FIG. For FBE access, CCA detection at the fixed frame configuration location starts to access the channel and initiates data transmission if there is an idle CCA period (less than 20us) in the channel. The time occupied by the transmission on the channel is relatively fixed and is at least 1 ms and at most 10 ms. The idle period is at least 5% of the channel occupancy time, and at the CCA time of the tail of the idle period, the device performs a new CCA detection to access the channel again. The result of adding the channel occupancy time and the idle period in the FBE mechanism is a fixed value and is called a frame period.

See FIG. The access mechanism is similar to the CSMA / CA mechanism of WiFi. The time and origin of the occupied channel change each time it is transmitted, and ECCA (Extended CCA) detection is performed before acquiring the channel. First, a random factor N is generated according to the size q of the contention window (CW) until the channel idle time becomes N times the CCA time (i.e., q). The channel must be idle to access the channel, and operate the data transfer process. The maximum time to occupy the channel is 13 ms. The ETSI LBE can be classified into two options, option A and option B, and the contention window of ETSI option B is fixed and is the most basic LBE format.

The LTE system supports two FDD and TDD duplex modes, and the two duplex modes have different frame configurations. As a common point of the two frame configurations, each of the radio frames consists of 10 1ms subframes. In the FDD system, a first type frame configuration is used as shown in Fig. 4, and a second type frame configuration is used in a TDD system as shown in Fig.

Currently, we have defined four kinds of LBT in 3GPP.

LBT category 1, LBT is not required.

LBT category 2, has a fixed backoff value, does not need a random backoff before sending a data burst, only performs CCA detection to access the channel, and the FBE is a special feature of the LBT category 2.

In LBT category 3 and LBT category 4, a random backoff value similar to CSMA / CA is used, a fixed contention window is used in LBT category 3, and ETSI LBE option B belongs to LBT category 3.

LBT category 4 is an LBT based on the modification of ETSI LBE option B and using load-based, and the contention window is either exponentially increasing or semi-statically set. To allow LTE-U and WiFi to coexist equally when WiFi adopts the CSMA / CA access mechanism due to the increased contention window index, the 3GPP requires that at least LTE-U use LBT Tape 4 in the downlink transmission. There are four possible categories in the LTE-U uplink LBT and there is no conclusion yet.

Whatever channel access mechanism is used for UL (uplink) transmission, the scheduled UE will have to perform time division multiplexing in a plurality of uplink transmission subframes. As a situation, for example, when the transmission time of uplink data of some UEs is long (for example, a plurality of subframes) and the data of some other UEs requires a very short transmission time (for example, one subframe) Do. As another situation, if the maximum channel occupied time of the UE is less than the set number of uplink subframes according to the regulations of some regions or countries, different UEs may perform time division multiplexing in the uplink subframe It becomes a problem that must be solved.

Unlike the allowed frequency band LTE, the UE of the unlicensed frequency band LTE-U must perform LBT before transmitting data. When performing time division multiplexing in unlicensed frequency bands, the UE transmitting the signal is inhibited in accessing the channel by the latter scheduled UE, and is time division multiplexed in the multi-UE case in the current LTE-U uplink transmission, And how to reserve resources for LBTs of newly accessed UEs in time division multiplexing.

Thus, in the embodiment according to the present invention, when the UL multi-UE is time division multiplexed in the unlicensed frequency band, a method of preliminarily allocating resources by taking an LBT or other operation of the UE is provided. Specifically, it is as follows.

The method for scheduling uplink transmission resources according to the embodiment of the present invention shown in FIG. 6 includes S101 and S102.

In S101, the base station confirms the pre-allocated resources in the uplink sub-frame. The preallocated resource is a transmission resource on the carrier without permission.

In S102, the base station transmits a notification of the pre-allocated resource in the uplink sub-frame to the UE.

According to the above method, a base station determines a pre-allocated resource in an uplink sub-frame, a pre-allocated resource is a transmission resource on an unauthorized carrier, and a base station transmits a pre-allocated resource Thereby preventing the UE from accessing the channel due to the failure of the UE to transmit an uplink signal in the preallocated resource, thereby preventing the scheduled UE from accessing the channel, Thereby allowing time division multiplexing of uplink transmission resources on the unlicensed carrier.

Here, UEs scheduled in a static manner, a semi-statically or a dynamic manner preliminarily allocate resources in uplink subframes used for performing operations such as LBTs.

Optionally, the base station transmits a notification of the pre-allocated resources in the uplink sub-frame to the UE in either a semi-statically or a dynamic manner.

Alternatively, when the base station transmits a notification of a pre-allocated resource in an uplink sub-frame to the UE in a quasi-static manner, the base station notifies the UE via non-physical layer signaling of the pre- And sends a notification.

When a base station transmits a notification of a pre-allocated resource in an uplink sub-frame to a UE in a dynamic manner, the base station transmits a notification of the pre-allocated resource in the uplink sub-frame to the UE via physical layer signaling.

Optionally, the pre-allocated resource is used by the UE to perform the LBT.

Optionally, the notification includes

Instruction information indicating that the UE should pre-allocate resources in an uplink sub-frame;

An uplink sub-frame in which a pre-allocated resource is located, and a position in an uplink sub-frame; And

And one of or any combination of the pre-allocated resource sizes in the uplink sub-frame including the pre-allocated resource.

Herein, the UE must preliminarily allocate a resource in the uplink subframe by adding 1 bit to the indicating information, for example, the UL grant, to the UE so as to allocate resources (for example, The symbol resource is the last one or N symbols, or it may be the first one or N symbols).

The pre-allocated resource size in the uplink sub-frame containing the pre-allocated resource can be pre-agreed and can be notified via signaling.

Optionally, the pre-allocated resource is located at the head or tail of at least one of the uplink sub-frames. A preallocated resource may be located in one uplink subframe and may be located in several uplink subframes, and may be located in the head, middle, or tail of the uplink subframe.

For example, the base station and the UE set the LBT subframe at N subframe intervals and the resource to be used for the LBT in the LBT subframe once. Of course, LBT subframes may be set at unequal intervals, and the number of LBT subframes is not limited to one.

Accordingly, the UE does not transmit a signal in the corresponding pre-allocated resource according to the setting of the base station. All scheduled UEs that have correctly received an UL grant (quasi-static scheduling or signaling used in dynamic scheduling) perform LBT on the pre-allocated resources to be used for the LBT set by the base station. A UE accessing a channel transmits an uplink signal on a scheduled uplink resource.

The uplink transmission method according to the embodiment of the present invention shown in FIG. 7 includes the following steps.

In S201, the UE confirms the pre-allocated resources in the uplink sub-frame. The preallocated resource is a transmission resource on the carrier without permission.

In S202, the UE determines that it has not transmitted an uplink signal in the pre-allocated resource.

Optionally, in the method, the UE performs an LBT on a pre-allocated resource if the channel is not accessible.

Alternatively, if the UE has accessed the channel, the UE transmits the uplink signal on the uplink resource scheduled by the base station.

Alternatively, the pre-allocated resources in the uplink sub-frame are preset.

Alternatively, the UE receives the notification of the pre-allocated resource in the uplink sub-frame transmitted by the base station in a quasi-static manner or in a dynamic manner, and confirms the pre-allocated resource in the uplink sub-frame by the notification.

In one embodiment, using a static set-up method, the base station and the UE may send (in some uplink subframes) all of the uplink subframes or uplink subframes (without some signaling indication) Resource allocation. As a workable method, the uplink subframe in which the resource for the LBT to be preallocated is located is agreed. The subframe is defined as an LBT subframe (this definition applies to all embodiments and is not repeatedly described), and a resource for the LBT to be preliminarily allocated (including at least the location and the size) is contracted in the LBT subframe do. As shown in FIG. 8, the BS and the UE may set LBT subframes at intervals of N subframes at an interval of LBT subframes and LBT subframes, The number may not be one, and the size of the Transmission Time Interval (TTI) used for each UE is less than or greater than 1, or equal to 1. The above description applies to all embodiments and is not repeatedly set). If the adopted LBT scheme is the LBT category 2, that is, if only the CCA detection is performed before transmitting the UL burst (the method described here applies to other access methods other than category 2, except for the other access methods) The size may preferably be an integer number of SC-FDM symbol lengths and may be an integer number of SC-FDM symbol lengths. The set LBT resource location may be the head of the established LBT sub-frame or the tail of the LBT sub-frame. If the transmission origin of the UL signal is a subframe boundary, preferably, the UE of the LBT subframe is a resource to be set for the LBT of the new UE to which the tail should access, and the UE transmitting the signal in the LBT subframe is a LBT The UE must stop signal transmission from the resource and the UE that has successfully received the UL grant corresponding to another subframe performs the LBT on the LBT resource of the corresponding LBT subframe. The UE that has accessed the channel performs the uplink transmission. If the origin of the UL signal transmission is not at the subframe boundary, the LBT resource is set at the head of the preferably set LBT subframe. Thus, all scheduled UEs preferably perform LBT without transmitting a signal at the set LBT resource at the head of the subframe. The U that accessed the channel performs the uplink transmission. The LBT resource may not only be a resource at the head or tail of the set LBT sub-frame, but may also be a resource at another position in the sub-frame.

In one embodiment, if a quasi-static set-up scheme is used, the base station may be configured to statically allocate a subset of all uplink subframes or uplink subframes through non-PHY layer signaling to make it a resource for the LBT You can tell. As a possible alternative, the uplink subframe for the LBT of the UE can be established via the non-physical layer signaling, and the resources for the LBT in the LBT subframe can be established by way of indicating and / (At least including position and size). For example, the base station may set the LBT subframe and the resource for the LBT in the LBT subframe once at intervals of N subframes, and may set the LBT subframe at unequal intervals according to the demand of the scheduling have. The set LBT resource size may preferably be an integer number of SC-FDM symbol lengths and may be an integer number of SC-FDM symbol lengths. The set LBT resource location may be the head of the established LBT sub-frame or the tail of the established LBT sub-frame. When the origin of the UL signal transmission is at the subframe boundary, the LBT resource is set in the tail of the LBT subframe desirably set, and the UE transmitting the signal in the LBT subframe transmits the signal in the LBT resource set in the subframe tail And all UEs that have successfully received an UL grant corresponding to another subframe perform LBT on the LBT resource of the set LBT subframe, i.e., the UE that has accessed the channel performs the uplink transmission. If the origin of the UL signal transmission is not at the subframe boundary, preferably, the LBT resource is set at the head of the LBT subframe. All scheduled UEs thus perform LBT, preferably without transmitting a signal at the set LBT resource at the head of the subframe. That is, the UE accessing the channel performs the uplink transmission. The location of the LBT resource may be the head and tail of the LBT subframe as well as other locations of the LBT subframe. FIG. 9 shows an example of semi-static setting in detail. If the LBT scheme used is the LBT category 2 (except for the other access schemes, the method described applies to other access schemes other than category 2), i.e. only CCA detection before transmitting the UL burst, The LBT subframe is set as a SRS (Sounding Reference Symbol) subframe by a Radio Resource Control (RRC) signaling, that is, the last SC-FDM symbol of the LBT subframe can not be used for data transmission. The base station also does not schedule the SRS, i.e., the LBT resource is the last one SC-FDM symbol of the LBT subframe and is used for channel access of the culled UE.

In one embodiment, if a dynamic setup method is used, the base station dynamically indicates through physical layer signaling that all uplink subframes or a subset of uplink subframes are reserved as resources for the LBT .

In the dynamic setting embodiment, 1 bit is added to the UL grant to inform the UE whether or not it is necessary to reserve resources to the PUSCH scheduled by this UL grant (for example, the last one / N Symbol, or the first / N symbols).

In a possible way, the base station dynamically indicates the uplink subframe in which the pre-allocated resource is located via physical layer signaling, and also provides resources for the LBT in the LBT subframe in a manner instructed and / or pre-agreed via signaling Setting. A base station is a method for dynamically indicating an uplink sub-frame in which a pre-allocated resource is located through physical layer signaling (dynamic signaling), and adds 1 bit to an UL grant, thereby transmitting a PUSCH To allocate resources for the LBT. The base station may set resources for the LBT sub-frame and the LBT in the LBT sub-frame in the UL sub-frame at the same interval or at different intervals according to the scheduling request, and the set LBT resource size is preferably an integer number of SC- And may be an irregular number of SC-FDM symbol lengths. The set LBT resource location may be the head of the established LBT sub-frame and may be the tail of the established LBT sub-frame. When the origin of the UL signal transmission is at the subframe boundary, the UE sets an LBT resource in a tail of a preferably set LBT subframe, and a UE transmitting a signal in the LBT subframe stops signal transmission in the LBT resource set in the subframe tail And all UEs successfully receiving an UL grant corresponding to another subframe perform LBT in the LBT resource of the established LBT subframe, i.e., the UE that has accessed the channel performs the uplink transmission. If the origin of the UL signal transmission is not at the subframe boundary, preferably, the LBT resource is set at the head of the LBT subframe. Thus, all successfully scheduled UEs perform the LBT without transmitting a signal in the LBT resource set at the head of the sub-frame, preferably. That is, the UE accessing the channel performs the uplink transmission. The location of the LBT resource may be the head and tail of the LBT subframe as well as other locations of the LBT subframe. 10 shows a dynamic setting example in detail. If the LBT scheme used is the LBT category 4 (the method described above is also suitable for other access methods other than category 4), the required uplink sub-frame is transmitted through the UL grant on the physical layer PDCCH or ePDCCH LBT subframe. If the start position of the signal is a subframe boundary, the last M SC-FDM symbols of the LBT subframe are used in the LBT and indicate by the UL grant that the access-succeeded UE transmits the signal or pre-commit.

Here, N and M in the embodiment according to the present invention are a predetermined positive integer.

As shown in FIG. 11, in a base station, an apparatus for scheduling uplink transmission resources according to an embodiment of the present invention includes a pre-allocation unit 11 for determining a pre-allocated resource in an uplink sub-frame; And a notification unit 12 that transmits a notification of the pre-allocated resources in the uplink sub-frame to the UE.

The pre-allocated resource is a transmission resource on the carrier without permission.

Optionally, the notifying unit transmits a notification of the pre-allocated resources in the uplink sub-frame to the UE in a quasi-static manner or in a dynamic manner.

Alternatively, if the notifying unit sends a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner, the notifying unit notifies the UE via non-physical layer signaling that the pre- And transmits a notification of the resource.

When the notifying unit sends a notification of a pre-allocated resource in the uplink sub-frame to the UE in a dynamic manner, the notifying unit sends a notification of the pre-allocated resource in the uplink sub-frame to the UE via physical layer signaling do.

Optionally, the pre-allocated resource is used by the UE to perform the LBT.

Optionally, the notification includes one of the following information or any combination thereof.

Indication information indicating that the UE should reserve resources in the uplink sub-frame.

The uplink sub-frame in which the pre-allocated resource is located, and the position in the uplink sub-frame.

The preallocated resource size in the uplink subframe containing the preallocated resource.

Optionally, the pre-allocated resource is located at the head or tail of at least one of the uplink sub-frames.

As shown in Fig. 12, on the UE side, an uplink transmission apparatus according to an embodiment of the present invention includes a first unit 21 for establishing a pre-allocated resource in an uplink sub-frame; And a second unit 22 for determining that the uplink signal is not transmitted from the pre-allocated resource.

The pre-allocated resource is a transmission resource on the carrier without permission.

Optionally, the second unit performs LBT on the pre-allocated resource if the UE to which the device belongs fails to access the channel.

Alternatively, if the UE to which the device belongs has accessed the channel, it transmits an uplink signal on the uplink resource scheduled by the base station.

Alternatively, the pre-allocated resources in the uplink sub-frame determined by the first unit are preset.

Alternatively, the first unit may be configured to receive a notification of a pre-allocated resource in an uplink sub-frame transmitted by the base station in a quasi-static manner or in a dynamic manner, and to transmit the pre-allocated resource in the uplink sub- I confirm it.

As shown in FIG. 13, at the base station side, another scheduling apparatus for uplink transmission resources according to an embodiment of the present invention includes a processor 500 for reading a program stored in a memory 520; And a transceiver 510 for transmitting and receiving data under the control of the processor 500. [

The processor 500 determines the pre-allocated resources in the uplink sub-frame. The pre-allocated resource is a transmission resource on the carrier without permission.

It also sends a notification of the pre-allocated resource in the uplink sub-frame to the UE via the transceiver 510. [

Optionally, the processor 500 transmits a notification of the pre-allocated resources in the uplink sub-frame to the UE in a quasi-static manner or a dynamic manner via the transceiver 510. [

Alternatively, when the processor 500 transmits a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner via the transceiver 510, And transmits a notification of the pre-allocated resources in the uplink sub-frame to the UE via physical layer signaling.

When the processor 500 transmits a notification of a pre-allocated resource in an uplink sub-frame to the UE in a dynamic manner via the transceiver 510, the processor 500 may send the notification of the pre- And transmits a notification of the pre-allocated resource in the uplink sub-frame to the UE.

Optionally, the pre-allocated resource is used by the UE to perform the LBT.

Optionally, the notification includes one of the following information or any combination thereof:

Indication information indicating that the UE should reserve resources in the uplink sub-frame.

The uplink sub-frame in which the pre-allocated resource is located, and the position in the uplink sub-frame.

The preallocated resource size in the uplink subframe containing the preallocated resource.

Optionally, the pre-allocated resource is located at the head or tail of at least one of the uplink sub-frames.

13, the bus architecture may include any number of interconnecting buses and bridges, and specifically includes one or more processors, including processor 500, and various circuits in memory, Lt; / RTI > The bus architecture can connect various other circuits, such as peripherals, current interrupters, and power management circuits. This is a matter known in the field of the present invention and will not be described any further. The bus interface provides an interface. The transceiver 510 may be a plurality of elements, i. E., Including a transmitter and a receiver, to provide elements for communicating with various other devices in the transmission medium. The processor 500 is responsible for managing bus architecture and general processing, and the memory 520 may store data used by the processor 500 when it operates.

As shown in Fig. 14, on the UE side, another uplink transmission apparatus of an embodiment according to the present invention includes a processor 600 for reading a program stored in a memory 620; And a transceiver 610 for transmitting and receiving data under the control of the processor 500.

The processor 600 determines the pre-allocated resources in the uplink sub-frame. The pre-allocated resource is a transmission resource on the carrier without permission.

Also, it is determined that the uplink signal is not transmitted from the preallocated resource.

Optionally, the processor 600 performs LBT on the pre-allocated resource if the UE to which the device belongs fails to access the channel.

Alternatively, if the UE to which the device belongs has accessed the channel, it transmits an uplink signal on the uplink resource scheduled by the base station.

Alternatively, the pre-allocated resources in the uplink sub-frame determined by the processor 600 are predetermined.

Alternatively, the processor 600 may receive a notification of a pre-allocated resource in an uplink sub-frame transmitted by the base station in a quasi-static or dynamic manner via the transceiver 610, Lt; / RTI >

14, the bus architecture may include any number of interconnecting buses and bridges, and specifically includes one or more processors, including processor 600, and various circuits in memory, including memory 620. [ Lt; / RTI > The bus architecture can connect various other circuits, such as peripherals, current interrupters, and power management circuits. This is a matter known in the field of the present invention and will not be described any further. The bus interface provides an interface. The transceiver 610 may be a plurality of elements, i. E., Including a transmitter and a receiver, to provide elements for communicating with various other devices in the transmission medium. For different user terminals, user interface 630 may be an interface of a device that can satisfy both peripheral connections and internal connections. The connected device may be, but is not limited to, a keypad, a display, a speaker, a microphone, a joystick, and the like. Processor 600 is responsible for bus architecture and general process management, and memory 620 can store data used by processor 600 when it is operating.

Therefore, considering the scheduling flexibility in the UL transmission of the LTE-U, in particular, when the allowed channel occupation time is short and the number of UL subframes is large, the UE requests time division multiplexing. The UE receiving the UL grant must perform the LBT before transmitting the uplink data if it has not accessed the channel. However, since a UE already accessing a channel and transmitting a signal inhibits access to another UE, regardless of where the LBT resource is located in the LBT subframe, the base station can determine the subframe and the LBT resource used for the LBT for the UE Should be set. Although the prior art has not yet proposed a specific implementation, according to the description of the embodiment of the present invention, flexible time division multiplexing of the LTE uplink in the unlicensed frequency band can be realized.

Obviously, those of ordinary skill in the art will be able to make various modifications and changes to the application and will not depart from the subject matter and scope of the present application. Thus, where such modifications and variations of the present application fall within the scope of the claims and the equivalents of the present application, the present application is intended to cover such modifications and changes.

This application claims the priority of Chinese patent application titled " Method and Apparatus for Constructing Primary Cell Changeable Cell "filed on September 25, 2015 with the Chinese Patent Office No. 201510625037.8, The entire contents of the above-mentioned Chinese patent application are incorporated herein by reference as part of this application.

Claims (18)

The base station establishing a pre-allocated resource in an uplink sub-frame, wherein the pre-allocated resource is a transmission resource on a carrier with no permission; And
The base station transmitting a notification of a pre-allocated resource in the uplink sub-frame to the UE
/ RTI > according to claim 1, The method according to claim 1,
Wherein the base station transmits a notification of a pre-allocated resource in the uplink sub-frame to a UE in a semi-statically or dynamically manner. 3. The method of claim 2,
Wherein the base station transmitting the notification of the pre-allocated resource in the uplink sub-frame to the UE comprises:
When the base station transmits a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner, the base station notifies the UE via non-physical layer signaling that the pre- And transmits the notification of
When the base station transmits a notice of a pre-allocated resource in the uplink sub-frame to the UE in a dynamic manner, the base station notifies the UE via physical layer signaling of the pre-allocated resource in the uplink sub-frame And transmitting the uplink transmission resource. The method according to claim 1,
Wherein the pre-allocated resource is used by the UE to perform LBT. The method according to claim 1,
The notification includes indication information indicating that the UE should reserve resources in an uplink sub-frame;
An uplink sub-frame in which the pre-allocated resource is located, and a position in an uplink sub-frame; And
Wherein one of the pre-allocated resource sizes in the uplink sub-frame including the pre-allocated resource or any combination thereof is included in the uplink sub-frame. The method according to claim 1,
Wherein the pre-allocated resource is located at the head or tail of at least one uplink sub-frame. The UE determining a pre-allocated resource in an uplink sub-frame, wherein the pre-allocated resource is a transmission resource on a carrier with no permission; And
The UE determines that it has not transmitted an uplink signal in the pre-allocated resource
/ RTI > 8. The method of claim 7,
The method comprises:
The UE performing an LBT on the pre-allocated resource if the channel is not accessed;
Or, if the UE has accessed the channel, transmitting an uplink signal on an uplink resource scheduled by the base station. 8. The method of claim 7,
The pre-allocated resources in the uplink sub-frame are preset,
The UE receives a notification informing a pre-allocated resource in the uplink sub-frame that the base station has transmitted in a quasi-static manner or a dynamic manner, and determines the pre-allocated resource in the uplink sub-frame by the notification The uplink transmission method. Allocating a pre-allocated resource in an uplink sub-frame, wherein the pre-allocated resource is a transmission resource on an unlicensed carrier; And
A notification unit for transmitting a notification of the pre-allocated resource in the uplink sub-frame to the UE;
And a scheduling unit for scheduling uplink transmission resources. 11. The method of claim 10,
The notification unit,
And transmitting a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static or dynamic manner. 12. The method of claim 11,
The notification unit,
When transmitting a notification of a pre-allocated resource in the uplink sub-frame to the UE in a quasi-static manner, the notifying unit notifies the UE via non-physical layer signaling of the pre-allocated resource in the uplink sub- And,
When transmitting a notification of a pre-allocated resource in the uplink sub-frame to the UE in a dynamic manner, the notifying unit transmits a notification of the pre-allocated resource in the uplink sub-frame to the UE via physical layer signaling Wherein the uplink transmission resource scheduling unit comprises: 11. The method of claim 10,
Wherein the pre-allocated resource is used by the UE to perform an LBT. 11. The method of claim 10,
The notification includes indication information indicating that the UE should reserve resources in an uplink sub-frame;
An uplink sub-frame in which the pre-allocated resource is located, and a position in an uplink sub-frame; And
And one of or any combination of the pre-allocated resource sizes in an uplink sub-frame including a pre-allocated resource. 11. The method of claim 10,
Wherein the pre-allocated resource is located at the head or tail of at least one uplink sub-frame. A first unit for determining a pre-allocated resource in an uplink sub-frame; And
And a second unit for determining that the uplink signal is not to be transmitted in the pre-allocated resource,
Wherein the pre-allocated resource is a transmission resource on a carrier without permission. 17. The method of claim 16,
The second unit comprising:
Performs LBT on the pre-allocated resource if the UE of the device fails to access the channel,
Or transmits an uplink signal on the uplink resource scheduled by the base station, when the belonging UE of the apparatus has accessed the channel. 17. The method of claim 16,
The pre-allocated resource in the uplink sub-frame is preset by the first unit,
Wherein the first unit is configured to receive a notification of a preallocated resource in the uplink subframe transmitted by a base station in a quasi-static manner or in a dynamic manner, and transmit the preallocated resource in the uplink subframe To the uplink transmission apparatus.

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